KR20160062422A - Glycol Dehydration System - Google Patents

Abstract

The present invention relates to a glycol dehydration system and method, and more specifically, to a glycol dehydration system comprising a glycol contactor which is integrated with a coalescer filter so that the glycol dehydration system can eliminate moisture from wet gas using the glycol contactor and can eliminate fine droplets as well. The glycol dehydration system comprises a glycol contactor, the glycol contactor comprising: a packed bed which eliminates moisture from wet gas; a demister which eliminates droplets; and a coalescer filter which eliminates fine droplets. The glycol dehydration system according to the present invention can generate dry gas by dehydrating wet gas using only a single device called a glycol contactor, and thus an installation space can be minimized by simplifying the configuration of the glycol dehydration system, thereby improving spatial utilization, reducing weight of the glycol dehydration system, and decreasing costs of the glycol dehydration system.

Description

Glycol Dehydration System

The present invention relates to a glycol dehydration system, and more particularly, to a glycol dehydration system for removing moisture in a gas using glycol, which can be applied to a dehydration system in a vessel or a topside of a floating marine structure.

In general, floating offshore plants with various uses are being operated in the ocean. Floating production storage offloading (FPSO), offshore platform, etc., which are moored at one point in the sea, .

The FPSO separates, processes and stabilizes a well fluid produced from a borehole into oil, gas and water to produce a transportable product state, for example Crude Oil ) And natural gas (NG: Natural Gas).

Natural gas can be produced by a gas production process that makes it possible to compress and dehydrate the gas separated from the oil jet mix and transport it overland.

The compression process during the gas production process is a process in which the gas is pressurized to maintain a high pressure until the separated gas from the well jet mix produced from the borehole is transported to the onshore. The gas separated from the oil jet mixture keeps high pressure and pressure decreases as the gas production process is repeated. To transport the gas to the land, the gas must maintain a certain level of pressure, so that the gas can be pressurized through the compression process. At this time, when the gas is pressurized, the pressure and the temperature are increased. Therefore, the pressurized gas is cooled to lower the temperature of the gas, and the pressurized gas is cooled to contain water. Moisture in the gas can corrode the five, valves and devices during transport and storage of natural gas, and can create hydrates and damage the device. Particularly in the liquefaction process, especially in a liquefied natural gas (LNG) plant, moisture must condense and seriously damage the equipment, so that the water content in the natural gas must be reduced to less than 1 ppm.

The dewatering process during the gas production process can remove moisture in the gas through the compression process as described above. In the dewatering process for removing moisture in the gas, there is a method of adsorbing water vapor using a hygroscopic liquid material or a dewatering solid material, and a method of condensing water vapor by compression or cooling. The most common method is adsorption using a hygroscopic solvent such as glycol.

FIG. 1 is a schematic diagram of a conventional glycol dehydration system for removing moisture in a gas using glycol, and FIG. 2 is a schematic diagram of a glycol contactor used in a conventional glycol dehydration system.

Referring to FIG. 1, in a conventional glycol dehydration system, a glycol contactor 10 for removing water using glycol as a solvent is used, and scrubbers 1 and 2 are disposed at the front and rear ends of the glycol contactor It is possible to remove moisture in the gas.

The gas compressed through the compressor is physically heated and the temperature is lowered through the cooler. In this process, water is generated, and a wet gas containing water is supplied to the glycol contactor 10 After the water in the gas is partially removed through the inlet scrubber 1 located at the front end of the glycol contactor 1, the water is injected into the glycol contactor to remove fine moisture through contact with the glycol, and then discharged to the upper portion of the glycol contactor The gas is passed through an outlet scrubber 2 installed at the rear end of the glycol contactor 2, and water can be removed to a desired level to produce natural gas.

Referring to FIG. 2, when the glycol is supplied through the lower end of the glycol contactor 10 and the glycol is supplied through the upper end of the glycol contactor 10, the glycol contacts the glycol contactor 20 , And the moisture-removed gas is discharged to the upper portion 20 of the glycol contactor.

Here, the water-absorbing glycol discharged to the lower part of the glycol contactor 10 is referred to as rich glycol, and the rich glycol is removed through the regenerating unit 20, And the water-removed glycol is fed back to the top of the column 10 and is called lean glycol.

Thus, in the conventional glycol dewatering system, in order to remove moisture in the gas, it is necessary to perform various stages of water removal process using an inlet scrubber, a glycol contactor, and an outlet scrubber to produce a natural gas with a desired level of moisture removed, There is a problem that the process is complicated and the efficiency is poor.

SUMMARY OF THE INVENTION The present invention has been made to overcome the above-mentioned problems, and it is an object of the present invention to provide a simplified glycol dehydration system as compared with the conventional glycol dehydration system.

According to an aspect of the present invention, there is provided a glycol dewatering system for removing moisture in a gas using glycol, the glycol dewatering system comprising a packed bed for removing moisture in a wet gas using glycol, ; A demister for removing droplets in the moisture-depleted gas from the packed bed; And a coalescer filter for removing fine droplets in the gas from which the droplets have been removed from the demister. BRIEF DESCRIPTION OF THE DRAWINGS FIG.

In the filling layer, a rich glycol produced by absorbing moisture in the wetting gas supplied from the lower end to the upper end of the glycol sprayed from the upper end to the lower end is discharged through the lower portion of the glycol contactor, May be supplied to the demister above the packed bed.

In the demister, a droplet having a diameter of 3 μm or more contained in the gas from which moisture is removed from the filling layer can be removed.

In the cholester filter, a fine droplet having a diameter of 0.3 mu m or more contained in the dry gas from which the droplet has been removed from the demister can be removed.

And a glycol regeneration unit for heating and separating the rich glycol discharged to the lower portion of the glycol contactor to form lean glycol and then supplying the lean glycol to the glycol contactor .

The glycol may be TEG (Tri Ethylene Glycol).

According to another aspect of the present invention, there is provided a glycol dewatering system for removing moisture in a gas using glycol, comprising: a glycol contactor which is a single unit in which a glycol dewatering process for removing moisture, droplets, A glycol dewatering system is provided that reduces weight and installation space.

The glycol dehydration system according to the present invention minimizes the area occupied by the glycol dehydration system in an offshore plant, thereby improving the space utilization, reducing the weight, and reducing the cost.

1 is a schematic diagram of a glycol dehydration system according to the prior art.
2 is a schematic diagram of a glycol contactor used in a prior art glycol dehydration system.
3 is a schematic diagram of a glycol dehydration system according to an embodiment of the present invention.
4 is a schematic diagram of a glycol contactor used in a glycol dehydration system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

FIG. 3 is a schematic diagram of a glycol dehydration system according to an embodiment of the present invention, and FIG. 4 is a schematic diagram of a glycol contactor used in a glycol dehydration system according to an embodiment of the present invention.

Referring to FIG. 3, the present invention is a glycol dewatering system 1 for removing moisture in a gas using glycol. The glycol dehydration system 1 includes a packed bed 11 for removing moisture in a wet gas using glycol, ; A demister (12) for removing droplets in the moisture-removed gas in the filling layer (11); And a glycol contactor (10) comprising a colaser filter (13, coalescer) for removing fine droplets in the gas from which droplets have been removed from the demister (12). The glycol may be TEG (Tri Ethylene Glycol).

In the filling layer 11, a rich glycol generated by absorbing moisture in the wetting gas supplied from the lower end to the upper end of the glycol sprayed from the upper end to the lower end of the filling layer 11 flows through the lower portion of the glycol contactor And the moisture-removed gas can be supplied to the demister 12 located above the filling layer 11. [

In the demister 12, the droplets can be removed from the gas from which the moisture supplied from the filling layer 11 is removed. The droplet to be removed from the demister 12 may have a diameter of 3 탆 or more and 99% or more of droplets having a diameter of 3 탆 or more in the gas supplied to the demister 12 may be removed. Lt; / RTI >

In the cholester filter 13, the droplet-removed gas is supplied from the demister 12, and the fine droplet can be removed. The diameter of the fine droplets to be removed from the colaser filter 13 may be 0.3 μm or more and 99% or more of the fine droplets having a diameter of 0.3 μm or more in the gas supplied to the colaser filter 13 may be removed. It may be a 0.003 ppm liquid droplet.

Meanwhile, the rich glycol discharged to the lower portion of the glycol contactor 10 is supplied to the glycol recovery unit 20 as a glycol containing a large amount of water (moisture saturated state) and can be regenerated. In the glycol regeneration unit 20, after the rich glycol is heated in the heat exchanger, moisture is removed from the separator, and lean glycol having a high glycol content can be discharged. The glycols discharged from the glycol recovery unit 20 can be supplied to the top of the filling layer 11 of the glycol contactor 10 and used to remove the moisture of the wetting gas.

The glycol dehydration system as described above can dehydrate the wet gas using a single unit glycol contactor to produce dry gas. Specifically, the dry gas can be produced by removing moisture from the wet gas by the filling layer of the glycol contactor and removing droplets and fine droplets by the demister and cholester.

As described above, in the conventional glycol dewatering system, a scrubber is essentially included as an additional device for removing moisture in the gas other than the glycol contactor. However, according to the present invention, by the colser filter integrated with the glycol contactor, It is possible to dehydrate the gas.

Further, the filling layer, the demister and the collet filter, which are capable of removing moisture, droplets and fine droplets in the gas, are mounted on a single unit called a collet contactor so that the dehydration process of the gas can be completed by the collet contactor Therefore, the equipment configuration of the glycol dehydration system can be simplified, and the installation space can be minimized, thereby improving the space utilization.

The glycol dehydration system of the present invention can be applied without limitation as long as it is a dehydration system in the ship or on the topside of a floating marine structure.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

10: glycol contactor
20: glycol recovery unit
11: filling layer
12: Demister
13: Colaser filter

Claims (7)

A glycol dehydration system for removing moisture in a gas using glycol,
A packed bed for removing water in a wet gas using a glycol;
A demister for removing droplets in the moisture-depleted gas from the packed bed; And
A coalescer filter for removing fine droplets in the droplet-free gas from the demister;
And a glycol contactor comprising the glycol contactor. The method according to claim 1,
In the filling layer,
Rich glycols generated by absorbing moisture in the wet gas supplied from the lower end to the upper end of the glycol sprayed from the upper end to the lower end are discharged through the lower portion of the glycol contactor,
And the dehydrated gas is supplied to a demister in the upper part of the packed bed. The method according to claim 1,
In the demister,
Wherein a droplet having a diameter of 3 mu m or more contained in the moisture-removed gas is removed from the filling layer. The method according to claim 1,
In the colaser filter,
Wherein a fine droplet having a diameter of 0.3 mu m or more contained in a dry gas from which droplets have been removed from the demister is removed. 3. The method of claim 2,
And a glycol regeneration unit for heating and separating the rich glycol discharged to the lower portion of the glycol contactor to form lean glycol and then supplying the lean glycol to the glycol contactor . ≪ / RTI > The method according to claim 1,
Wherein the glycol is TEG (Tri Ethylene Glycol). A glycol dehydration system for removing moisture in a gas using glycol,
And a glycol contactor, which is a single unit in which a glycol dewatering process for removing water, droplets and fine droplets in the wet gas is performed, thereby simplifying the structure.

Images